Hammody Z, Huleihel M, Salman A, Argov S, Moreh R, Katzir A, Mordechai S
Department of Physics and the Cancer Research Center, Ben-Gurion University, Beer-Sheva 84105, Israel.
J Microsc. 2007 Nov;228(Pt 2):200-10. doi: 10.1111/j.1365-2818.2007.01840.x.
The present study focuses on evaluating the potential of flattened AgClBr fibre-optic evanescent wave spectroscopy (FTIR-FEWS) technique for detection and identification of cancer cells in vitro using cell culture as a model system. The FTIR-FEWS results are compared to those from FTIR-microspectroscopy (FTIR-MSP) method extensively used to identify spectral properties of intact cells. Ten different samples of control and malignant cells were measured in parallel by the above two methods. Our results show a significant similarity between the results obtained by the two methodologies. The absorbance level of Amide I/Amide II, phosphates and carbohydrates were significantly altered in malignant compared to the normal cells using both systems. Thus, common biomarkers such as Amide I/Amide II, phosphate and carbohydrate levels can be derived to discern between normal and cancer cells. However, marked differences are also noted between the two methodologies in the protein bands due to CH3 bending vibration (1480-1350 cm(-1)). The spectral differences may be attributed to the variation in the penetration depth of the two methodologies. The use of flattened fibre rather than the standard cylindrical fibre has several practical advantages and is considered as an important step towards in vivo measurements in real time, such as that of skin nevi and melanoma using special designs of fibre-optic-based sensors.
本研究聚焦于评估扁平AgClBr光纤倏逝波光谱(FTIR - FEWS)技术在以细胞培养为模型系统的体外癌细胞检测与识别中的潜力。将FTIR - FEWS的结果与广泛用于识别完整细胞光谱特性的FTIR - 显微光谱(FTIR - MSP)方法的结果进行比较。通过上述两种方法平行测量了10个不同的对照细胞和恶性细胞样本。我们的结果表明这两种方法所获得的结果具有显著相似性。使用这两种系统时,与正常细胞相比,恶性细胞中酰胺I/酰胺II、磷酸盐和碳水化合物的吸光度水平均有显著变化。因此,可以得出诸如酰胺I/酰胺II、磷酸盐和碳水化合物水平等常见生物标志物来区分正常细胞和癌细胞。然而,由于CH3弯曲振动(1480 - 1350 cm(-1)),在两种方法的蛋白质条带中也注意到明显差异。光谱差异可能归因于这两种方法穿透深度的变化。使用扁平光纤而非标准圆柱形光纤具有几个实际优点,并且被认为是朝着实时体内测量迈出的重要一步,例如使用基于光纤传感器的特殊设计对皮肤痣和黑色素瘤进行实时体内测量。